Adaptive dead-time control

ABSTRACT

A DC-to-DC converter includes first and second switches connected to each other at a node and biased by PWM pulses. A timing module determines a first time difference between a first edge of a first signal at the node and a first edge of a second signal at a control terminal of the first switch, and a second time difference between a second edge of the first signal and a second edge of the second signal. The first and second edges of the second signal correspond to first and second edges of one of the PWM pulses, respectively. A delay module delays the first and second edges of the second signal based on the first and second time differences, respectively. The delay module delays an edge of one of the PWM pulses based on an amount of change in a voltage output by a charge pump.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. Pat. No. 13/680,364 filed Nov. 19, 2012, which claims the benefit of U.S. Provisional Application No. 61/567,938 filed on Dec. 7, 2011. The disclosures of the above applications are incorporated herein by reference in their entirety.

FIELD

The present disclosure relates generally to DC-to-DC voltage converters and more particularly to dead-time control in DC-to-DC voltage converters.

BACKGROUND

The background description provided herein is for the purpose of generally presenting the context of the disclosure. Work of the presently named inventors, to the extent it is described in this background section, as well as aspects of the description that may not otherwise qualify as prior art at the time of filing, are neither expressly nor impliedly admitted as prior art against the present disclosure.

Referring now to FIGS. 1A and 1B, a DC-to-DC converter (hereinafter converter) 100 is shown. In FIG. 1A, the converter 100 includes a control module 102, a dead time control module 103, a high-side switch T_(HS), a low-side switch T_(LS), an inductor L, a capacitor C_(out), and a load 104. The high-side switch T_(HS) and the low-side switch T_(LS) (collectively switches) are connected in series. The control module 102 generates PWM pulses that control on and off times of the switches. The dead time control module 103 controls dead times of the switches (explained below). The inductor L is connected to a junction of the switches and is connected in series with the capacitor C_(out) as shown. The load 104 is connected in parallel to the capacitor C_(out) as shown. The converter 100 receives an input voltage V_(dd) and outputs an output voltage V_(out) across the load 104.

In FIG. 1B, an inductor current I_(L) increases when the high-side switch T_(HS) is turned on while the low-side switch T_(LS) is turned off and decreases when the high-side switch T_(HS) is turned off while the low-side switch T_(LS) is turned on. A voltage V_(LX) at the junction of the switches varies with time t as shown in FIG. 1B. A time interval between opening (i.e., turning off) one switch (e.g., the high-side switch T_(HS)) and closing (i.e., turning on) another switch (e.g., the low-side switch T_(LS)) is called a dead-time and is shown by dotted circles in FIG. 1B. Body diodes D_(HS) and D_(LS), which are respectively integrated with the high-side switch T_(HS) and the low-side switch T_(LS), conduct during dead times causing power loss. Power loss also occurs due to reverse recovery. Power losses due to conduction of the body diodes and reverse recovery are pronounced at high switching frequencies of the PWM pulses and low output voltages (V_(out)) of the converter. The dead times therefore need to be minimized to reduce the power losses.

Referring now to FIGS. 2A-2C, different modes of operation of a converter and corresponding dead times are shown. For example, in FIG. 2A, the converter operates in a Buck continuous conduction mode (CCM) with a heavy load, where the inductor current I_(L) is always positive. In FIG. 2B, the converter operates in a Buck or Boost forced CCM with a light load, where the inductor current I_(L) can be positive and negative. In FIG. 2C, the converter operates in a Boost CCM with a heavy load, where the inductor current I_(L) is always negative. In each mode, the dead times shown need to be minimized to reduce the power losses.

SUMMARY

A DC-to-DC converter shown in FIG. 5A includes first and second transistors each driven by pulse-width modulated (PWM) pulses and each having first and second terminals and a control terminal. The first terminal of the first transistor is connected to a supply voltage, the second terminal of the first transistor and the first terminal of the second transistor are connected to a node, the second terminal of the second transistor is connected to ground, and the node is connected to an inductance that is connected in series to a load. A first timing module determines a first time difference between a first edge of a first signal at the node and a first edge of a second signal at the control terminal of the first transistor. The first edge of the second signal corresponds to a first edge of one of the PWM pulses. A second timing module determines a second time difference between a second edge of the first signal at the node and a second edge of the second signal at the control terminal of the first transistor. The second edge of the second signal corresponds to a second edge of the one of the PWM pulses. A delay module delays the first edge of the second signal at the control terminal of the first transistor based on the first time difference and delays the second edge of the second signal at the control terminal of the first transistor based on the second time difference.

A DC-to-DC converter shown in FIG. 5B includes first and second transistors each driven by pulse-width modulated (PWM) pulses and each having first and second terminals and a control terminal. The first terminal of the first transistor is connected to a supply voltage, the second terminal of the first transistor and the first terminal of the second transistor are connected to a node, the second terminal of the second transistor is connected to ground, and the node is connected to an inductance that is connected in series to a load. A first timing module determines a first time difference between a first edge of a first signal at the node and a first edge of a second signal at the control terminal of the second transistor. The first edge of the second signal corresponds to a first edge of one of the PWM pulses. A second timing module determines a second time difference between a second edge of the first signal at the node and a second edge of the second signal at the control terminal of the second transistor. The second edge of the second signal corresponds to a second edge of the one of the PWM pulses. A delay module delays the first edge of the second signal at the control terminal of the second transistor based on the first time difference and delays the second edge of the second signal at the control terminal of the second transistor based on the second time difference.

A DC-to-DC converter shown in FIG. 5C includes first and second transistors each driven by pulse-width modulated (PWM) pulses and each having first and second terminals and a control terminal. The first terminal of the first transistor is connected to a supply voltage, the second terminal of the first transistor and the first terminal of the second transistor are connected to a node, the second terminal of the second transistor is connected to ground, and the node is connected to an inductance that is connected in series to a load. A first timing module determines a first time difference between a first edge of a first signal at the node and a first edge of a second signal at the control terminal of the first transistor. The first edge of the second signal corresponds to a first edge of one of the PWM pulses. A second timing module determines a second time difference between a second edge of the first signal at the node and a second edge of the second signal at the control terminal of the first transistor. The second edge of the second signal corresponds to a second edge of the one of the PWM pulses. A third timing module determines a third time difference between the first edge of the first signal at the node and a first edge of a third signal at the control terminal of the second transistor. The first edge of the third signal corresponds to the first edge of the one of the PWM pulses. A first delay module delays the first edge of the second signal at the control terminal of the first transistor based on the first time difference and delays the second edge of the second signal at the control terminal of the first transistor based on the second time difference. A second delay module delays the first edge of the third signal at the control terminal of the second transistor based on the third time difference and does not delay a second edge of the third signal at the control terminal of the second transistor, wherein the second edge of the third signal corresponds to the second edge of the one of the PWM pulses.

A DC-to-DC converter shown in FIG. 5D includes first and second transistors each driven by pulse-width modulated (PWM) pulses and each having first and second terminals and a control terminal. The first terminal of the first transistor is connected to a supply voltage, the second terminal of the first transistor and the first terminal of the second transistor are connected to a node, the second terminal of the second transistor is connected to ground, and the node is connected to an inductance that is connected in series to a load. A first timing module determines a first time difference between a first edge of a first signal at the node and a first edge of a second signal at the control terminal of the first transistor. The first edge of the second signal corresponds to a first edge of the one of the PWM pulses. A second timing module determines a second time difference between the first edge of the first signal at the node and a first edge of a third signal at the control terminal of the second transistor. The first edge of the third signal corresponds to the first edge of the one of the PWM pulses. A third timing module determines a third time difference between a second edge of the first signal at the node and a second edge of the third signal at the control terminal of the second transistor. The second edge of the third signal corresponds to a second edge of the one of the PWM pulses. A first delay module delays the first edge of the second signal at the control terminal of the first transistor based on the first time difference and does not delay a second edge of the second signal at the control terminal of the first transistor. The second edge of the second signal corresponds to the second edge of the one of the PWM pulses. A second delay module delays the first edge of the third signal at the control terminal of the second transistor based on the second time difference and delays the second edge of the third signal at the control terminal of the second transistor based on the third time difference.

A DC-to-DC converter shown in FIG. 4A includes first and second transistors each driven by pulse-width modulated (PWM) pulses and each having first and second terminals and a control terminal. The first terminal of the first transistor is connected to a supply voltage, the second terminal of the first transistor and the first terminal of the second transistor are connected to a node, the second terminal of the second transistor is connected to ground, and the node is connected to an inductance that is connected in series to a load. A first timing module determines a first time difference between a first edge of a first signal at the node and a first edge of a second signal at the control terminal of the first transistor. The first edge of the second signal corresponds to a first edge of one of the PWM pulses. A second timing module determines a second time difference between a second edge of the first signal at the node and a second edge of the second signal at the control terminal of the first transistor. The second edge of the second signal corresponds to a second edge of the one of the PWM pulses. A third timing module determines a third time difference between the second edge of the first signal at the node and a first edge of a third signal at the control terminal of the second transistor. The first edge of the second signal corresponds to the second edge of the one of the PWM pulses. A fourth timing module determines a fourth time difference between the first edge of the first signal at the node and a second edge of the third signal at the control terminal of the second transistor. The second edge of the third signal corresponds to the first edge of the one of the PWM pulses. A first delay module delays the first edge of the second signal at the control terminal of the first transistor based on the first time difference and delays the second edge of the second signal at the control terminal of the first transistor based on the second time difference. A second delay module delays the first edge of the third signal at the control terminal of the second transistor based on the third time difference and delays the second edge of the third signal at the control terminal of the second transistor based on the fourth time difference.

Further areas of applicability of the present disclosure will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples are intended for purposes of illustration only and are not intended to limit the scope of the disclosure.

BRIEF DESCRIPTION OF THE DRAWINGS

The present disclosure will become more fully understood from the detailed description and the accompanying drawings, wherein:

FIG. 1A is a schematic of a DC-to-DC converter according to the prior art;

FIG. 1B depicts graphs of an inductor current (I_(L)) and a voltage (V_(LX)) at a junction of switches of the DC-to-DC converter as functions of time according to the prior art;

FIG. 2A depicts graphs of I_(L) and V_(LX) as functions of time for a DC-to-DC converter operating in a Buck continuous conduction mode (CCM) with a heavy load;

FIG. 2B depicts graphs of I_(L) and V_(LX) as functions of time for a DC-to-DC converter operating in a Buck or Boost forced continuous conduction mode (CCM) with a light load;

FIG. 2C depicts graphs of I_(L) and V_(LX) as functions of time for a DC-to-DC converter operating in a Boost continuous conduction mode (CCM) with a heavy load;

FIG. 3A is a schematic of a DC-to-DC converter that reduces dead times in Buck or Boost forced continuous conduction mode (CCM) with a light load;

FIG. 3B depicts graphs of I_(L) and V_(LX) as functions of time for the DC-to-DC converter of FIG. 3A operating in a Buck continuous conduction mode (CCM) with a heavy load;

FIG. 3C depicts graphs of I_(L) and V_(LX) as functions of time for the DC-to-DC converter of FIG. 3A operating in a Buck or Boost forced continuous conduction mode (CCM) with a light load;

FIG. 3D depicts graphs of I_(L) and V_(LX) as functions of time for the DC-to-DC converter of FIG. 3A operating in a Boost continuous conduction mode (CCM) with a heavy load;

FIG. 4A is a schematic of a DC-to-DC converter according to the present disclosure that reduces dead times in various modes including Buck CCM with a heavy load, Buck or Boost forced CCM with a light load, and Boost CCM with a heavy load;

FIG. 4B depicts graphs of I_(L) and V_(LX) as functions of time for the DC-to-DC converter of FIG. 4A operating in a Buck continuous conduction mode (CCM) with a heavy load;

FIG. 4C depicts graphs of I_(L) and V_(LX) as functions of time for the DC-to-DC converter of FIG. 4A operating in a Buck or Boost forced continuous conduction mode (CCM) with a light load;

FIG. 4D depicts graphs of I_(L) and V_(LX) as functions of time for the DC-to-DC converter of FIG. 4A operating in a Boost continuous conduction mode (CCM) with a heavy load;

FIG. 5A is a schematic of a DC-to-DC converter according to the present disclosure that reduces dead times in Boost CCM using two feedback loops for a high-side switch of the converter;

FIG. 5B is a schematic of a DC-to-DC converter according to the present disclosure that reduces dead times in Buck CCM using two feedback loops for a low-side switch of the converter;

FIG. 5C is a schematic of a DC-to-DC converter according to the present disclosure that reduces dead times in Boost mode using two feedback loops for a high-side switch of the converter and one feedback loop for a low-side switch of the converter;

FIG. 5D is a schematic of a DC-to-DC converter according to the present disclosure that reduces dead times in Buck mode using one feedback loop for a high-side switch of the converter and two feedback loop for a low-side switch of the converter;

FIG. 6A is a schematic of the DC-to-DC converter of FIG. 4A further comprising gate sensors and common-mode feedback modules according to the present disclosure; and

FIG. 6B is a schematic of a charge pump used in the DC-to-DC converter of FIG. 6A.

DETAILED DESCRIPTION

The following description is merely illustrative in nature and is in no way intended to limit the disclosure, its application, or uses. For purposes of clarity, the same reference numbers will be used in the drawings to identify similar elements. As used herein, the phrase at least one of A, B, and C should be construed to mean a logical (A or B or C), using a non-exclusive logical or. It should be understood that steps within a method may be executed in different order without altering the principles of the present disclosure.

As used herein, the term module may refer to, be part of, or include an Application Specific Integrated Circuit (ASIC); an electronic circuit; a combinational logic circuit; a field programmable gate array (FPGA); a processor (shared, dedicated, or group) that executes code; other suitable components that provide the described functionality; or a combination of some or all of the above, such as in a system-on-chip. The term module may include memory (shared, dedicated, or group) that stores code executed by the processor.

The term code, as used above, may include software, firmware, and/or microcode, and may refer to programs, routines, functions, classes, and/or objects. The term shared, as used above, means that some or all code from multiple modules may be executed using a single (shared) processor. In addition, some or all code from multiple modules may be stored by a single (shared) memory. The term group, as used above, means that some or all code from a single module may be executed using a group of processors or a group of execution engines. For example, multiple cores and/or multiple threads of a processor may be considered to be execution engines. In various implementations, execution engines may be grouped across a processor, across multiple processors, and across processors in multiple locations, such as multiple servers in a parallel processing arrangement. In addition, some or all code from a single module may be stored using a group of memories.

The apparatuses and methods described herein may be implemented by one or more computer programs executed by one or more processors. The computer programs include processor-executable instructions that are stored on a non-transitory tangible computer readable medium. The computer programs may also include stored data. Non-limiting examples of the non-transitory tangible computer readable medium are nonvolatile memory, magnetic storage, and optical storage.

The present disclosure relates to reducing dead times (i.e., conduction times of body diodes of high and low side drivers) of DC-to-DC converters. Specifically, the present disclosure relates to reducing the dead times in various modes of operation of the DC-to-DC converters irrespective of load conditions. For example, the dead times can be reduced according to the present disclosure in DC-to-DC converters operating in Buck continuous conduction mode (CCM) with a heavy load, Buck or Boost forced CCM with a light load, and Boost CCM with a heavy load.

One way to reduce the dead times is to prevent the body diodes from conducting and turning on the high-side switch T_(HS) or the low-side switch T_(LS) before the respective body diodes can conduct. Accordingly, the load current I_(L) will flow through the high-side switch T_(HS) or the low-side switch T_(LS) instead of flowing through the respective body diodes.

Referring now to FIGS. 3A-3D, a DC-to-DC converter (hereinafter converter) 200 that reduces dead times in Buck or Boost forced CCM with a light load is shown. In FIG. 3A, the converter 200 includes the high-side switch T_(HS), the low-side switch T_(LS), the inductor L, the capacitor C_(out), and the load 104. The high-side switch T_(HS) and the low-side switch T_(LS) (collectively switches) are connected in series. The inductor L is connected to the junction of the switches and is connected in series with the capacitor C_(out) as shown. The load 104 is connected in parallel to the capacitor C_(out) as shown. The PWM pulses generated by the PWM module 102 (not shown) control the on and off times of the switches. The converter 200 receives the input voltage V_(dd) and outputs the output voltage V_(out) across the load 104.

To reduce the dead times, the converter 200 further includes a feedback loop for each switch. The feedback loops compare timings of gate and drain voltage transitions of the switches. The feedback loops delay the PWM pulses that are output to the gates of the switches based on the timings to reduce the dead times.

The word transition as used herein means a rising edge or a falling edge of a signal (e.g., a PWM pulse, a voltage, or a current) when the signal begins to rise from a low value or fall from a high value, respectively. Accordingly, a gate turn-on transition for the high-side switch T_(HS) is a falling edge of a gate-to-source voltage of the high-side switch T_(HS) since the high-side switch T_(HS) is shown as a PMOS device. A gate turn-off transition for the high-side switch T_(HS) is a rising edge of the gate-to-source voltage of the high-side switch T_(HS) since the high-side switch T_(HS) is shown as a PMOS device.

Conversely, a gate turn-on transition for the low-side switch T_(LS) is a rising edge of a gate-to-source voltage of the low-side switch T_(LS) since the low-side switch T_(LS) is shown as an NMOS device. A gate turn-off transition for the low-side switch T_(LS) is a falling edge of the gate-to-source voltage of the low-side switch T_(LS) since the low-side switch T_(LS) is shown as an NMOS device. Similarly, a falling V_(LX) transition is a falling edge of the voltage V_(LX), and a rising V_(LX) transition is a rising edge of the voltage V_(LX).

The feedback loop for the high-side switch T_(HS) includes a timing module 202, a charge pump 204, a delay module 206, and an inverting driver 208. The feedback loop for the low-side switch T_(LS) includes a timing module 210, a charge pump 212, a delay module 214, and an inverting driver 216.

The inputs of the delay modules 206 and 214 receive the PWM pulses from the PWM module 102. The delay module 206 delays a rising edge of a PWM pulse (since T_(HS) is a PMOS device) based on an output voltage of the charge pump 204 and propagates a falling edge of a PWM pulse without delay. The inverting driver 208 inverts the output of the delay module 206 and outputs the inverted output of the delay module 206 to the gate of the high-side switch T_(HS). The delay module 214 delays a falling edge of a PWM pulse (since T_(LS) is an NMOS device) based on an output voltage of the charge pump 212 and propagates a rising edge of a PWM pulse without delay. The inverting driver 216 inverts the output of the delay module 214 and outputs the inverted output of the delay module 214 to the gate of the low-side switch T_(LS).

In the feedback loop for the high-side switch T_(HS), the timing module 202 has an inverting input and a non-inverting input. The inverting input is connected to the gate of the high-side switch T_(HS) (since T_(HS) is a PMOS device). The non-inverting input is connected to the junction of the switches. Accordingly, the inverting input senses a falling edge of a gate voltage of the high-side switch T_(HS), and the non-inverting input senses a rising edge of a voltage V_(LX) at the junction of the switches.

Suppose a falling transition of the gate voltage of the high-side switch T_(HS) occurs at time t1, and a rising transition of the voltage V_(LX) occurs at time t2. The timing module 202 has two outputs: out1 and out2. If t1 is before t2, the timing module 202 outputs a pulse having a pulse width (t2-t1) on the output out1, and out2 is low. Conversely, if t2 is before t1, out1 is low, and the timing module 202 outputs a pulse having a pulse width (t1-t2) on the output out2.

The charge pump 204 has two inputs that respectively receive the outputs out1 and out2 of the timing module 202, and an output that outputs a voltage that increases or decreases based on the outputs out1 and out2 of the timing module 202. For example, the output voltage of the charge pump 204 increases when the timing module 202 outputs a pulse on the output out1 and decreases when the timing module 202 outputs a pulse on the output out2. The amount by which the output of the charge pump increases or decreases depends respectively on the pulse widths on the outputs out1 and out2.

The delay module 206 delays a rising edge of a PWM pulse. The amount of delay is based on the output of the charge pump 204. For example, the delay increases or decreases based on whether the output of the charge pump 204 increases or decreases. Further, the amount by which the delay increases or decreases depends on the amount by which the output of the charge pump 204 increases or decreases. The inverting driver 208 inverts the output of the delay module 206 and outputs the inverted output of the delay module 206 to the gate of the high-side switch T_(HS).

In the feedback loop for the low-side switch T_(LS), the non-inverting input of the timing module 210 is connected to the gate of the low-side switch T_(LS) (since T_(LS) is an NMOS device). The inverting input is connected to the junction of the switches. Accordingly, the non-inverting input senses a rising edge of a gate voltage of the low-side switch T_(LS), and the inverting input senses a falling edge of the voltage V_(LX) at the junction of the switches.

Suppose a falling transition of the voltage V_(LX) occurs at time t1, and a rising transition of the gate voltage of the low-side switch T_(LS) occurs at time t2. The timing module 210 has two outputs: out1 and out2. If t2 is before t1, the timing module 210 outputs a pulse having a pulse width (t1-t2) on the output out1, and out2 is low. If t1 is before t2, out1 is low, and the timing module 210 outputs a pulse having a pulse width (t2-t1) on the output out2.

The charge pump 212 has two inputs that respectively receive the outputs out1 and out2 of the timing module 210, and an output that outputs a voltage that increases or decreases based on the outputs out1 and out2 of the timing module 210. For example, the output voltage of the charge pump 212 increases when the timing module 210 outputs a pulse on the output out1 and decreases when the timing module 210 outputs a pulse on the output out2. The amount by which the output of the charge pump increases or decreases depends respectively on the pulse widths of the outputs out1 and out2.

The delay module 214 delays a falling edge of a PWM pulse. The amount of delay is based on the output of the charge pump 212. For example, the delay increases or decreases based on whether the output of the charge pump 212 increases or decreases. Further, the amount by which the delay increases or decreases depends on the amount by which the output of the charge pump 212 increases or decreases. The inverting driver 216 inverts the output of the delay module 214 and outputs the inverted output of the delay module 214 to the gate of the low-side switch

In use, when the high-side switch T_(HS) is off and the low-side switch T_(LS) is on, a rising edge of a PWM pulse is output to turn on the high-side switch T_(HS). The delay modules 206 and 214 receive the rising edge of the PWM pulse. The delay module 214 propagates the rising edge of the PWM pulse without delay. The inverting driver 216 outputs a falling edge to the gate of the low-side switch T_(LS), which turns off the low-side switch T_(LS). If the inductor current flows into the junction of the switches at that time, the voltage V_(LX) starts to increase.

The timing module 202 senses a time difference between a time at which the voltage V_(LX) has risen and a time at which the gate-to-source voltage of the high-side switch T_(HS) transitions and begins to fall (i.e., the gate turn-on transition of the high-side switch T_(HS)). The delay module 206 delays the gate turn-on transition of the high-side switch T_(HS) based on the time difference to reduce this time difference, i.e., the dead time.

Conversely, when the high-side switch T_(HS) is on and the low-side switch T_(LS) is off, a falling edge of a PWM pulse is output to turn off the high-side switch T_(HS). The delay modules 206 and 214 receive the falling edge of the PWM pulse. The delay module 206 propagates the falling edge of the PWM pulse without delay. The inverting driver 208 outputs a rising edge to the gate of the high-side switch T_(HS), which turns off the high-side switch T_(HS). If the inductor current flows out of the junction of the switches at that time, the voltage V_(LX) starts to decrease.

The timing module 210 senses a time difference between a time at which the voltage V_(LX) has fallen and a time at which the gate-to-source voltage of the low-side switch T_(LS) transitions and begins to rise (i.e., the gate turn-on transition of the low-side switch T_(LS)). The delay module 214 delays the gate turn-on transition of the low-side switch T_(LS) based on the time difference to reduce this time difference, i.e., the dead time.

The delays generated by the delay modules 206 and 214 adjust (reduce) the dead times as shown in FIG. 3C. The delays, however, reduce the dead times only when the converter 200 operates in Buck or Boost CCM with a light load. The delays increase the dead times when the inductor current flows only out of the junction of the switches (i.e., when the converter 200 operates in Buck CCM with a heavy load) as shown in FIG. 3B and when the inductor current flows only into the junction of the switches (i.e., when the converter 200 operates in Boost CCM with a heavy load) as shown in FIG. 3D.

Referring now to FIGS. 4A-4D, a converter 300 that reduces dead times in various modes is shown. The converter 300 reduces dead times irrespective of load conditions. For example, the converter 300 reduces dead times when operating in Buck CCM with a heavy load, Buck or Boost forced CCM with a light load, and Boost CCM with a heavy load.

In FIG. 4A, the converter 300 includes all of the components of the converter 200 shown in FIG. 3A except the delay modules 206 and 214. The converter 300 further includes an additional feedback loop for the high-side switch T_(HS) comprising a timing module 306 and a charge pump 308 and an additional feedback loop for the low-side switch T_(LS) comprising a timing module 310 and a charge pump 312. The converter 300 also includes a delay module 302 for the high-side switch T_(HS) and a delay module 304 for the low-side switch T_(LS). The inputs of the delay modules 302 and 304 receive the PWM pulses from the PWM module 102.

The delay module 302 delays a rising edge of a PWM pulse based on the output of the timing module 202 and the charge pump 204 and delays a falling edge of a PWM pulse based on an output of the timing module 306 and the charge pump 308. The delay module 304 delays a falling edge of a PWM pulse based on the output of the timing module 210 and the charge pump 212 and delays a rising edge of a PWM pulse based on an output of the timing module 310 and the charge pump 312.

The connections and functions of the timing module 202, the charge pump 204, the timing module 210, and the charge pump 212 are the same as in the converter 200. The connections and functions of the timing module 306, the charge pump 308, the timing module 310, and the charge pump 312 are as follows.

In the feedback loop for the high-side switch T_(HS), the timing module 306 has an inverting input and a non-inverting input. The inverting input is connected to the junction of the switches, and the non-inverting input is connected to the gate of the high-side switch T_(HS). Accordingly, the inverting input senses a falling edge of the voltage V_(LX) at the junction of the switches, and the non-inverting input senses a rising edge of the gate voltage of the high-side switch T_(HS).

Suppose a rising transition of the gate voltage of the high-side switch T_(HS) occurs at time t1, and a falling transition of the voltage V_(LX) occurs at time t2. The timing module 306 has two outputs: out1 and out2. If t1 is before t2, the timing module 306 outputs a pulse having a pulse width (t2-t1) on the output out1, and out2 is low. Conversely, if t2 is before t1, out1 is low, and the timing module 306 outputs a pulse having a pulse width (t1-t2) on the output out2.

The charge pump 308 has two inputs that respectively receive the outputs out1 and out2 of the timing module 306, and an output that outputs a voltage that increases or decreases based on the outputs out1 and out2 of the timing module 306. For example, the output voltage of the charge pump 308 increases when the timing module 306 outputs a pulse on the output out1 and decreases when the timing module 306 outputs a pulse on the output out2. The amount by which the output of the charge pump increases or decreases depends respectively on the pulse widths on the outputs out1 and out2.

The delay module 302 delays a falling edge of a PWM pulse by an amount based on the output of the charge pump 308. For example, the delay increases or decreases based on whether the output of the charge pump 308 increases or decreases. Further, the amount by which the delay increases or decreases depends on the amount by which the output of the charge pump 308 increases or decreases. The inverting driver 208 inverts the output of the delay module 302 and outputs the inverted output of the delay module 302 to the gate of the high-side switch T_(HS).

In the feedback loop for the low-side switch T_(LS), the inverting input of the timing module 310 is connected to the gate of the low-side switch T_(LS), and the non-inverting input is connected to the junction of the switches. Accordingly, the inverting input senses a falling edge of the gate voltage of the low-side switch T_(LS), and the non-inverting input senses a rising edge of the voltage V_(LX) at the junction of the switches.

Suppose a falling transition of the gate voltage of the low-side switch T_(LS) occurs at time t1 and a rising transition of the voltage V_(LX) occurs at time t2. The timing module 310 has two outputs: out1 and out2. If t1 is before t2, the timing module 310 outputs a pulse having a pulse width (t2-t1) on the output out1, and out2 is low. If t2 is before t1, out1 is low, and the timing module 310 outputs a pulse having a pulse width (t1-t2) on the output out2.

The charge pump 312 has two inputs that respectively receive the outputs out1 and out2 of the timing module 310, and an output that outputs a voltage that increases or decreases based on the outputs out1 and out2 of the timing module 310. For example, the output voltage of the charge pump 312 increases when the timing module 310 outputs a pulse on the output out1 and decreases when the timing module 310 outputs a pulse on the output out2. The amount by which the output of the charge pump increases or decreases depends respectively on the pulse widths of the outputs out1 and out2.

The delay module 304 delays a rising edge of a PWM pulse by an amount based on the output of the charge pump 312. For example, the delay increases or decreases based on whether the output of the charge pump 312 increases or decreases. Further, the amount by which the delay increases or decreases depends on the amount by which the output of the charge pump 312 increases or decreases. The inverting driver 216 inverts the output of the delay module 304 and outputs the inverted output of the delay module 304 to the gate of the low-side switch T_(LS).

In use, when a rising edge of the PWM pulse is received, the delay module 302 delays the rising edge according to the feedback received from the timing module 202 and the charge pump 204, and the delay module 304 delays the rising edge according to the feedback received from the timing module 310 and the charge pump 312. When a falling edge of the PWM pulse is received, the delay module 302 delays the falling edge according to the feedback received from the timing module 306 and the charge pump 308, and the delay module 304 delays the falling edge according to the feedback received from the timing module 210 and the charge pump 212.

For example, suppose that the high-side switch T_(HS) is off, the low-side switch T_(LS) is on, and the delay modules 302 and 304 receive a rising edge of the PWM pulse to turn on the high-side switch T_(HS). Suppose also that the inductor current I_(L) flows out of the junction of the switches at that time. Since the rising edge of the PWM pulse turns on the high-side switch T_(HS), the rising edge of the PWM pulse may be called a turn-on transition of the converter 300.

In the feedback loop of the high-side switch T_(HS), the gate-to-source voltage of the high-side switch T_(HS) falls before the voltage V_(LX) can rise. Accordingly, at the inputs of the timing module 202, time t1 at which the gate-to-source voltage of the high-side switch T_(HS) starts falling is before time t2 at which the voltage V_(LX) starts rising. In other words, the gate turn-on transition of the high-side switch T_(HS) occurs earlier than a rising V_(LX) transition. The output out1 of the timing module 202 outputs a pulse of pulse width (t2-t1) at the output out1, and the output out2 of the timing module 202 is low. The output voltage of the charge pump 204 increases proportionally to the pulse width (t2-t1). The delay module 302 delays the rising edge of the PWM pulse proportionally to the increase in the output voltage of the charge pump 204. The process continues until the output voltage of the charge pump 204 rails at V_(dd). The amount of delay continues to increase and reaches a maximum value when the output voltage of the charge pump 204 rails at V_(dd). At this point the feedback loop of the high-side switch T_(HS) is saturated.

In the feedback loop of the low-side switch T_(LS), the gate-to-source voltage of the low-side switch T_(LS) is falling, and the voltage V_(LX) is rising. Suppose that at the inputs of the timing module 310, time t1 at which the gate-to-source voltage of the high-side switch T_(HS) starts falling is later than time t2 at which the voltage V_(LX) starts rising. In other words, the gate turn-off transition of the low-side switch T_(LS) occurs later than a rising V_(LX) transition. The output out2 of the timing module 310 outputs a pulse of pulse width (t1-t2) at the output out2, and the output out1 of the timing module 310 is low. The output voltage of the charge pump 312 decreases proportionally to the pulse width (t1-t2). The delay module 304 decreases the delay of the rising edge of the PWM pulse proportionally to the decrease in the output voltage of the charge pump 312. Over several cycles (i.e., PWM pulses) the amount of delay continues to decrease until a time difference between the times t1 and t2 becomes nearly zero.

At this point, the dead time during the turn-on transitions of the converter 300 is nearly zero when the inductor current I_(L) flows out of the junction of the switches at that time. In this manner, when the inductor current I_(L) flows out of the junction of the switches during the rising edges of the PWM pulses (i.e., during the turn on transitions of the converter 300), the feedback loop of the high-side switch T_(HS) saturates, and the feedback loop of the low-side switch T_(LS) adjusts (reduces) the dead time during the rising edges of the PWM pulse (i.e., during the turn-on transitions of the converter 300).

Now suppose that the high-side switch T_(HS) is off, the low-side switch T_(LS) is on, the delay modules 302 and 304 receive a rising edge of the PWM pulse to turn on the high-side switch T_(HS), and the inductor current I_(L) flows into the junction of the switches at that time. In the feedback loop of the low-side switch T_(LS), the gate-to-source voltage of the low-side switch T_(LS) falls before the voltage V_(LX) can rise. Accordingly, at the inputs of the timing module 310, time t1 at which the gate-to-source voltage of the low-side switch T_(LS) starts falling is before time t2 at which the voltage V_(LX) starts rising. In other words, the gate turn-off transition of the low-side switch T_(LS) occurs earlier than a rising V_(LX) transition. The output out1 of the timing module 310 outputs a pulse of pulse width (t2-t1) at the output out1, and the output out2 of the timing module 310 is low. The output voltage of the charge pump 312 increases proportionally to the pulse width (t2-t1). The delay module 304 delays the rising edge of the PWM pulse proportionally to the increase in the output voltage of the charge pump 312. The process continues until the output voltage of the charge pump 312 rails at V_(dd). The amount of delay continues to increase and reaches a maximum value when the output voltage of the charge pump 312 rails at V_(dd). At this point the feedback loop of the low-side switch T_(LS) is saturated.

In the feedback loop of the high-side switch T_(HS), the gate-to-source voltage of the high-side switch T_(HS) is falling, and the voltage V_(LX) is rising. Suppose that at the inputs of the timing module 202, time t1 at which the gate-to-source voltage of the high-side switch T_(HS) starts falling is later than time t2 at which the voltage V_(LX) starts rising. In other words, the gate turn-on transition of the high-side switch T_(HS) occurs later than a rising V_(LX) transition. The output out2 of the timing module 202 outputs a pulse of pulse width (t1-t2) at the output out2, and the output out1 of the timing module 202 is low. The output voltage of the charge pump 204 decreases proportionally to the pulse width (t1-t2). The delay module 302 decreases the delay of the rising edge of the PWM pulse proportionally to the decrease in the output voltage of the charge pump 204. Over several cycles (i.e., PWM pulses) the amount of delay continues to decrease until a time difference between the times t1 and t2 becomes nearly zero.

At this point, the dead time during the turn-on transitions of the converter 300 is nearly zero when the inductor current I_(L) flows into the junction of the switches at that time. In this manner, when the inductor current I_(L) flows into the junction of the switches during the rising edges of the PWM pulse (i.e., during the turn-on transitions of the converter 300), the feedback loop of the low-side switch T_(LS) saturates, and the feedback loop of the high-side switch T_(HS) adjusts (reduces) the dead time during the rising edges of the PWM pulse (i.e., during the turn-on transitions of the converter 300).

Similar analysis can be obtained during a turn-off transition of the converter 300 (i.e., when a falling edge of a PWM pulse is output to turn off the high-side switch T_(HS)). The delays generated by the delay modules 302 and 304 adjust (reduce) the dead times when the converter 300 operates in various modes irrespective of load conditions as shown in FIGS. 4B-4D.

In summary, the timing module 306 senses a time difference between a time at which the voltage V_(LX) transitions and begins to fall and a time at which the gate-to-source voltage of the high-side switch T_(HS) transitions and begins to rise (i.e., the gate turn-off transition of the high-side switch T_(HS)). The delay module 302 delays the gate turn-off transition of the high-side switch T_(HS) by delaying the falling edge of the PWM pulse based on the time difference to reduce this time difference, i.e., the dead time.

The timing module 202 senses a time difference between a time at which the voltage V_(LX) transitions and begins to rise and a time at which the gate-to-source voltage of the high-side switch T_(HS) transitions and begins to fall (i.e., the gate turn-on transition of the high-side switch T_(HS)). The delay module 302 delays the gate turn-on transition of the high-side switch T_(HS) by delaying the rising edge of the PWM pulse based on the time difference to reduce this time difference, i.e., the dead time.

The timing module 310 senses a time difference between a time at which the voltage V_(LX) transitions and begins to rise and a time at which the gate-to-source voltage of the low-side switch T_(LS) transitions and begins to fall (i.e., the gate turn-off transition of the low-side switch T_(LS)). The delay module 304 delays the gate turn-off transition of the low-side switch T_(LS) by delaying the rising edge of the PWM pulse based on the time difference to reduce this time difference, i.e., the dead time.

The timing module 210 senses a time difference between a time at which the voltage V_(LX) transitions and begins to fall and a time at which the gate-to-source voltage of the low-side switch T_(LS) transitions and begins to rise (i.e., the gate turn-on transition of the low-side switch T_(LS)). The delay module 304 delays the gate turn-on transition of the low-side switch T_(LS) by delaying the falling edge of the PWM pulse based on the time difference to reduce this time difference, i.e., the dead time.

Referring now to FIGS. 5A-5D, additional converters that reduce dead times are shown. Each of the converters operates in a particular mode and reduces dead times in the particular mode using a plurality but not all of the feedback loops shown in FIG. 4A. For example, in FIG. 5A, a converter 400-1 operating in Boost CCM reduces dead times using only the delay module 302, the timing module 306, the charge pump 308, the timing module 202, and the charge pump 204. In FIG. 5B, a converter 400-2 operating in Buck CCM reduces dead times using only the delay module 304, the timing module 310, the charge pump 312, the timing module 210, and the charge pump 212. In FIG. 5C, a converter 400-3 operating in Boost mode reduces dead times using only the delay modules 302 and 304, the timing module 306, the charge pump 308, the timing module 202, the charge pump 204, the timing module 210, and the charge pump 212. In FIG. 5D, a converter 400-4 operating in Buck mode reduces dead times using only the delay modules 302 and 304, the timing module 202, the charge pump 204, the timing module 310, the charge pump 312, the timing module 210, and the charge pump 212.

Referring now to FIGS. 6A and 6B, a converter 500 comprising a plurality of gate sensors and a plurality of common-mode feedback modules is shown. In FIG. 6A, the converter 500 includes all of the components of the converter 300 shown in FIG. 4A. The converter 500 further includes gate sensors 502 and 504 and common-mode feedback modules 506 and 508. The gate sensors 502 and 504 trip at gate-to-source voltages between the plateau voltages and gate-to-source threshold voltages of the high-side switch T_(HS) and the low-side switch T_(LS), respectively. The common-mode feedback modules 506 and 508 prevent the charge pumps from railing to V_(dd).

A plateau voltage is defined in practice as the gate-to-source voltage at which the transistor delivers a current substantially equal to the inductor current. The gate-to-source threshold voltage is a gate-to-source voltage at which the transistor turns on.

The trip voltages of the gate sensors 502 and 504 may be adjusted between the plateau voltage and the gate-to-source threshold voltage based on the inductor current I_(L). For example, for light load, the trip voltage may be set closer to the gate-to-source threshold voltage, and for heavy load, the trip voltage may be set farther from the gate-to-source threshold voltage and closer to the plateau voltage. The adjustment of the trip voltages of the gate sensors 502 and 504 based on the inductor current I_(L) further compensates for variations in dead time as a function of load current.

In FIG. 6A, each of the common-mode feedback modules 506, 508 includes a circuit that functions as a charge-injecting common-mode voltage controller. These modules prevent the charge pumps from railing to V_(dd) or ground.

In FIG. 6B, an example of a charge pump 550 is shown. The charge pump 550 includes current sources 552 and 554 and switches 556 and 558. The switches 556 and 558 of a charge pump (e.g., one of the charge pumps 308, 204, 312, or 212) are respectively connected to the outputs out1 and out2 of a corresponding timing module (e.g., one of the timing modules 306, 202, 310, or 210) to which the charge pump is connected.

Throughout the present disclosure, the high-side switch T_(HS) is shown as a PMOS device, and the low-side switch T_(LS) is shown as an NMOS device for example only. Instead, the high-side switch T_(HS) can be an NMOS device, and the low-side switch T_(LS) can be a PMOS device. Accordingly, while polarities of various signals including PWM pulses, voltages, and currents are discussed throughout the disclosure according to examples shown, the polarities will be opposite if the high-side switch T_(HS) is an NMOS device, and the low-side switch T_(LS) is a PMOS device instead.

The broad teachings of the disclosure can be implemented in a variety of forms. Therefore, while this disclosure includes particular examples, the true scope of the disclosure should not be so limited since other modifications will become apparent to the skilled practitioner upon a study of the drawings, the specification, and the following claims. 

What is claimed is:
 1. A DC-to-DC converter comprising: first and second switches that are connected to each other at a node, that are connected in series across first and second potentials, and that are biased by pulse-width modulated (PWM) pulses; an inductance connected between the node and a load; a timing module that determines a first time difference between a first edge of a first signal at the node and a first edge of a second signal at a control terminal of the first switch and that determines a second time difference between a second edge of the first signal at the node and a second edge of the second signal at the control terminal of the first switch, wherein the first and second edges of the second signal correspond to first and second edges of one of the PWM pulses, respectively; a delay module that delays the first and second edges of the second signal at the control terminal of the first switch based on the first and second time differences, respectively; and a charge pump that outputs a voltage, wherein the delay module delays an edge of one of the PWM pulses based on an amount of change in the voltage output by the charge pump.
 2. The DC-to-DC converter of claim 1 wherein: the first and second edges of the first signal at the node are falling and rising edges, respectively; the first and second edges of the second signal at the control terminal of the first switch are rising and falling edges, respectively; and the first and second edges of the one of the PWM pulses are falling and rising edges, respectively.
 3. The DC-to-DC converter of claim 1 wherein: the voltage increases by an amount proportional to a difference between the first and second times in response to the first edge of the second signal at the control terminal of the first switch occurring at a first time and the first edge of the first signal at the node occurring at a second time that is later than the first time; and the delay module delays the first edge of the one of the PWM pulses based on the amount of increase in the voltage.
 4. The DC-to-DC converter of claim 1 wherein: the voltage decreases by an amount proportional to a difference between the first and second times in response to the first edge of the second signal at the control terminal of the first switch occurring at a first time and the first edge of the first signal at the node occurring at a second time that is earlier than the first time; and the delay module delays the first edge of the one of the PWM pulses based on the amount of decrease in the voltage.
 5. The DC-to-DC converter of claim 1 wherein: the voltage increases by an amount proportional to a difference between the first and second times in response to the second edge of the second signal at the control terminal of the first switch occurring at a first time and the second edge of the first signal at the node occurring at a second time that is later than the first time; and the delay module delays the second edge of the one of the PWM pulses based on the amount of increase in the voltage.
 6. The DC-to-DC converter of claim 1 wherein: the voltage decreases by an amount proportional to a difference between the first and second times in response to the second edge of the second signal at the control terminal of the first switch occurring at a first time and the second edge of the first signal at the node occurs at a second time that is earlier than the first time; and the delay module delays the second edge of the one of the PWM pulses based on the amount of decrease in the voltage.
 7. The DC-to-DC converter of claim 1 wherein: the timing module determines a third time difference between the first edge of the first signal at the node and a first edge of a third signal at the control terminal of the second switch, wherein the first edge of the third signal corresponds to the first edge of the one of the PWM pulses; and the delay module delays the first edge of the third signal at the control terminal of the second switch based on the third time difference and does not delay a second edge of the third signal at the control terminal of the second switch, wherein the second edge of the third signal corresponds to the second edge of the one of the PWM pulses.
 8. The DC-to-DC converter of claim 7 wherein: the first and second edges of the first signal at the node are falling and rising edges, respectively; the first and second edges of the second signal at the control terminal of the first switch are rising and falling edges, respectively; the first and second edges of the third signal at the control terminal of the second switch are rising and falling edges, respectively; and the first and second edges of the one of the PWM pulses are falling and rising edges, respectively.
 9. The DC-to-DC converter of claim 7 wherein: the voltage increases by an amount proportional to a difference between the first and second times in response to the first edge of the third signal at the control terminal of the second switch occurring at a first time and the first edge of the first signal at the node occurring at a second time that is later than the first time; and the delay module delays the first edge of the one of the PWM pulses based on the amount of increase in the voltage.
 10. The DC-to-DC converter of claim 7 wherein: the voltage decreases by an amount proportional to a difference between the first and second times in response to the first edge of the third signal at the control terminal of the second switch occurring at a first time and the first edge of the first signal at the node occurring at a second time that is earlier than the first time; and the delay module delays the first edge of the one of the PWM pulses based on the amount of decrease in the voltage.
 11. A DC-to-DC converter comprising: first and second switches that are connected to each other at a node, that are connected in series across a supply voltage and a reference potential, and that are biased by pulse-width modulated (PWM) pulses; an inductance connected between the node and a load; a timing module that determines a first time difference between a first edge of a first signal at the node and a first edge of a second signal at a control terminal of the first switch, a second time difference between a second edge of the first signal at the node and a second edge of the second signal at the control terminal of the first switch, a third time difference between the second edge of the first signal at the node and a first edge of a third signal at the control terminal of the second switch, and a fourth time difference between the first edge of the first signal at the node and a second edge of the third signal at the control terminal of the second switch, wherein the first and second edges of the second signal and the second and first edges of the third signal respectively correspond to first and second edges of one of the PWM pulses; a plurality of charge pumps that output respective voltages based on the first, second, third, and fourth time differences; and a delay module that delays the first and, second edges of the second signal at the control terminal of the first switch based on the first and second time differences, respectively, that delays the first and second edges of the third signal at the control terminal of the second switch based on the third and fourth time differences, respectively.
 12. The DC-to-DC converter of claim 11, wherein the delay module delays one or more of the first and second edges of the one of the PWM pulses based on one or more of the first, second, third, and fourth time differences.
 13. The DC-to-DC converter of claim 11, wherein: the first and second edges of the first signal at the node are falling and rising edges, respectively; the first and second edges of the second signal at the control terminal of the first switch are rising and falling edges, respectively; the first and second edges of the third signal at the control terminal of the second switch are falling and rising edges, respectively; and the first and second edges of the one of the PWM pulses are falling and rising edges, respectively.
 14. The DC-to-DC converter of claim 11 further comprising a feedback module that senses a plurality of the voltages output by the charge pumps, that computes an average voltage of the plurality of the voltages, and that injects a charge into the outputs of the respective charge pumps, wherein the charge is based on a difference between the average voltage and the supply voltage.
 15. The DC-to-DC converter of claim 11 further comprising a sensor that senses current through the inductance and that outputs the second signal in response to a control voltage at the control terminal of the first switch being greater than or equal to a predetermined voltage, wherein the predetermined voltage is set between a threshold voltage at which the first switch turns on and a plateau voltage of the first switch depending on the load.
 16. The DC-to-DC converter of claim 11 further comprising a sensor that senses current through the inductance and that outputs the third signal in response to a control voltage at the control terminal of the second switch being greater than or equal to a predetermined voltage, wherein the predetermined voltage is set between a threshold voltage at which the second switch turns on and a plateau voltage of the second switch depending on the load. 